Landscape metrics for characterization of forest landscapes in a sustainable management framework: Potential application and prevention of misuse

HAL Id: hal-00883396

https://hal.archives-ouvertes.fr/hal-00883396

Submitted on 1 Jan 2009

HAL is a multi-disciplinary open access

archive for the deposit and dissemination of

sci-entific research documents, whether they are

pub-lished or not. The documents may come from

teaching and research institutions in France or

abroad, or from public or private research centers.

L’archive ouverte pluridisciplinaire HAL, est

destinée au dépôt et à la diffusion de documents

scientifiques de niveau recherche, publiés ou non,

émanant des établissements d’enseignement et de

recherche français ou étrangers, des laboratoires

publics ou privés.

landscapes in a sustainable management framework:

Potential application and prevention of misuse

Emilio R. Diaz-Varela, Manuel F. Marey-Pérez, Antonio Rigueiro-Rodriguez,

Pedro Álvarez-Álvarez

To cite this version:

Ann. For. Sci. 66 (2009) 301 Available online at: c

 INRA, EDP Sciences, 2009 www.afs-journal.org

DOI:10.1051/forest/2009004

Original article

Landscape metrics for characterization of forest landscapes in a

sustainable management framework: Potential application and

prevention of misuse

Emilio R. D

iaz

-V

arela

_*

_{, Manuel F. M}

arey

_-P

erez

_´

_{, Antonio R}

igueiro

_-R

odriguez

_,

Pedro Á

lvarez

-Á

lvarez

1_{Department of Agroforestry Engineering, University of Santiago de Compostela, Spain} 2_{Department of Vegetal Production, University of Santiago de Compostela, Spain}

(Received 19 October 2008; accepted 6 June 2009)

Keywords: landscape indices/ scale/

pattern analysis/

sustainable forest management/ FORSEE project

Abstract

• The use of landscape indices in the analysis of forest landscapes offers great potential for integration of spatial pattern information in management processes, but requires understanding of the limitations and correct interpretation of results. In this sense, awareness of scale effects on landscape indices is essential, especially when the data available is restricted to low-resolution maps.

• In this study, developed within the framework of the FORSEE project, the objective was to define accurately the potential usefulness of applying landscape indices to low-resolution maps commonly used in forestry studies. Landscape indices were applied to two maps differing in spatial resolution, and subsets were defined for three spatial extensions. Correlation analysis and comparison of the re-sults were carried out to enable identification of the most suitable indices for use with low resolution data.

• The analysis enabled identification of the least scale-dependent indices, which are thus more useful for extrapolating results from low-resolution data. In general terms, diversity and edge indices pro-vided the best results.

• We conclude that some (but not all) of the landscape indices can be used to analyse low-resolution maps with acceptable results. Additional advice is made to prevent misuse of the application of land-scape indices.

Mots-clés : indices de paysage/ échelle/

modèle d’analyse/ gestion durable des forêts/ projet FORSEE

Résumé – Indices quantitatifs de paysage pour une caractérisation des paysages forestiers dans le cadre d’une gestion durable : application potentielle et prévention de mauvaise utilisation.

• L’utilisation d’indices de paysage dans l’analyse des paysages forestiers offre un grand potentiel pour l’intégration d’informations de modèles spatiaux dans les processus de gestion, mais exige la compréhension des limitations et une interprétation correcte de résultats. Dans ce sens, la conscience des effets d’échelle sur les indices de paysage est essentielle, particulièrement quand les données dis-ponibles sont limitées aux cartes de basse résolution.

• Dans cette étude, développée dans le cadre du projet FORSEE, l’objectif était de définir précisément l’utilité potentielle d’application des indices de paysage aux cartes de basse résolution, généralement utilisées dans les études de sylviculture. Les indices de paysage ont été appliqués à deux cartes dif-férant par la résolution spatiale et les sous-ensembles ont été définis pour trois extensions spatiales. Une analyse de corrélation et la comparaison des résultats ont été effectuées pour permettre l’identi-fication des indices les plus appropriés pour une utilisation avec des données de basse résolution. • L’analyse a permis l’identification des indices les moins dépendants de l’échelle, qui sont ainsi plus utiles pour extrapoler les résultats de données de basse résolution. En termes généraux, la diversité et des indices de bord ont fourni les meilleurs résultats.

• Nous concluons que certains (mais pas tous) indices de paysage peuvent être utilisés pour analyser les cartes de basse résolution avec des résultats acceptables. Un conseil supplémentaire est fait pour prévenir une mauvaise utilisation des indices de paysage.

* Corresponding author: emilio.diaz@usc.es

1. INTRODUCTION

Sustainable forestry management pursues multifunctional-ity of forest ecosystems and landscapes, and assumes that forests can assume a variety of functions in addition to pro-ductive functions, namely: carbon sequestration, watershed protection, biodiversity, recreation, cultural and social uses, etc. (Andersson et al.,2004; Von Gadow et al.,2000). In or-der to maintain or enhance such multifunctionality, the spatial complexity or heterogeneity of forest landscapes has been re-ported to be a critical factor (Bengtsson et al.,2000; Franklin and Forman,1987; Lindenmayer et al., 2000) as it can have positive effects on both the ecological (ecosystem stability, species diversity. . . ) and productive (increased yield, resis-tance to pests) characteristics of forests. Consequently, assess-ment of the spatial heterogeneity of forest landscapes should be included in the indicators used in sustainable forestry man-agement across Europe.

To improve the situation regarding indicators for sustain-able forest management, the EU funded the INTERREG III-B FORSEE project to assess the relevance, feasibility and costs of such indicators. The indicators analysed in the project in-clude six criteria (carbon stocks, health, productive functions, biological diversity, soil and water protection, and socioeco-nomic functions). The study and characterization of the het-erogeneity and complexity of forest ecosystems, as well as their fragmentation, are included within biological diversity, by means of the application of landscape indices or metrics.

Application of landscape metrics, defined as quantitative indices that describe structures or patterns in landscapes (O’Neill et al., 1988), has numerous precedents in different fields (Botequilha and Ahern,2002; Botequilha et al., 2006; Gustafson,1998; Hargis et al.,1998; Hoover and Parker,1991; O’Neill et al., 1988). Specifically, landscape metrics have been used for the analysis of forestry related issues, such as: fragmentation and other forest transformations (Löfman and Kouki,2003; McAlpine and Eyre,2002; Riitters et al.,2002; Trani and Giles,1999); the effects of wildfires on forest cover (Gonzalez et al.,2000; Lloret et al.,2002; Romme,1982); dif-ferentiation between native and introduced forests (Saura and Carballal,2004), and to address wildlife habitat concerns in developing decision-making support tools in forest ecosystem management (Falcao and Borges,2005). Nevertheless, and de-spite their extensive use, the precise meaning of each metric may be uncertain and the interpretation of the results compli-cated by different factors (Corry and Nassauer,2005; Li and Wu,2004). One of the questions that requires better under-standing is the response of metrics to changes in scale. This problem has been approached in numerous studies with re-spect to both spatial extent (Saura and Martínez-Millán,2001; Turner et al.,1989; Wu et al.,2002) and grain size or resolu-tion (Baldwin et al.,2004; Saura,2004; Turner et al., 1989; Wu,2004), which are considered as two fundamental compo-nents of the scale (Gustafson,1998). Specifically, the effect of the resolution of cartographic data on landscape metrics has been investigated in the search for mathematical relationships across scales, which could enable prediction of the behaviour of indices with changes in scale. Studies have included

vary-ing the resolution of categorical maps (Baldwin et al.,2004; Turner et al.,1989), use of remote sensed data (Frohn,1998; Frohn and Hao,2006; Saura,2004), and development of arti-ficial landscape maps simulated with neutral models (Li et al., 2005; Saura,2002). In general it was found that the trends in results can vary greatly when applied to different map exten-sions and/or resolutions (depending on the type of metric and the way it is applied), and that in order to avoid misleading results, such resolutions must match the capability of the land-scape metric to reflect the characteristics of the spatial hetero-geneity. These are important constraints considering that much readily available spatial data is often of low resolution, and its application could lead to problems due to the confusing ef-fects that low resolution and aggregation of data have on the results of landscape metrics (Baldwin et al.,2004; Benson and MacKenzie,1995; Saura,2004). On the other hand, the devel-opment of fine-grained maps for large extensions may involve costs that are difficult for many forestry or environmental re-lated organizations and enterprises. Despite these shortcom-ings, landscape metrics can be considered for use as indicators of forest heterogeneity by planners and technicians once their scientific soundness and technical reliability, as well as their comprehensibility and low-cost implementation have been im-proved.

The objective of this study was to evaluate the potential usefulness of the application of landscape indices to low-resolution maps commonly used in forestry studies, by the identification of possible inaccuracies derived from the appli-cation of a series of landscape indices to coarse-scaled car-tographic data commonly used in regional and sub-regional forestry studies. The specific aim was to identify which indices demonstrate most robustness and scale-independence in their application to the aforementioned data sources, in order to im-prove the quality of the analysis of heterogeneity in forested landscapes. The approach used was to compare the results of the application of indices to an example of a categorical map developed under an EFICS protocol, (see Material and meth-ods) and to a high-resolution categorical map developed for this project. Correlation analysis of the results of each met-ric in several subsets of the maps was applied to search for common trends in the results derived from both sources. This allowed us to define and finally recommend which indices can be used, and the situations in which they can be used, for the analysis of heterogeneity in low-resolution cartographical data.

The reference framework for the study was biological

di-versity, as defined in the above-mentioned FORSEE project, in

which a series of landscape indices were specified for the char-acterization of forest fragmentation, heterogeneity and con-nectivity.

2. MATERIAL AND METHODS 2.1. Study area

Landscape metrics and forest landscapes Ann. For. Sci. 66 (2009) 301

Figure 1. Location of the study area.

Coruña and Lugo (Galicia, NW Spain). The area is characterized by uneven relief, with the altitude ranging from 400 to 700 m. More than 30% of the area consists of forest zones, noteworthy because of the extensions of native deciduous forests and Eucalyptus spp. and Pinus spp. plantations.

2.2. Cartography used

Two digital, vectorial format cartography sources were used: The Forest Map of Spain, developed at a national level, and a project specific map, developed for the study area, which was used as the Ground-Truth Map (hereafter referred to as GTM).

The Forest Map of Spain (FMS) is developed by the Spanish Min-istry of Environment, and updated on a ten yearly basis as support for the National Forest Inventory. It follows the EU regulations estab-lished by the EFICS (European Forestry Information and Commu-nication System) regarding actions addressing the availability of de-tailed data about forests in all European Union member states (Päivi-nen and Köhl, 2005). As such, it was considered here as an adequate example for testing the behaviour of landscape metrics in maps cur-rently used for the assessment of forest statistics. The Forest Map of Spain is currently the most comprehensive work developed at the national level as regards forest mapping. It is developed at a carto-graphic scale of 1:50 000, the Minimum Mapping Unit (MMU) is 25 000 m2_{for forest land and 62 500 m}2_{for other land use classes,} and it includes alpha-numerical information about fifteen descrip-tors related to forest ecology and structure. The map is developed from the interpretation of aerial photographs, followed by vector-ization of the delineated land-cover polygons over high resolution ortho-photographs and codification of the polygons with their land-use code, and the accuracy of data is checked in the field.

The Ground Truth Map (GTM) was developed for the project study area by means of analogical photo-interpretation of high-resolution orthophotographies, supported by a cadastral vector map. As a result, a map of a cartographic scale of 1:2 000, with an MMU of 25 m2_{, was obtained. Even when the accuracy of the GTM was} not evaluated, the standards followed in previous studies (see Marey, 2003) were applied in elaboration of the map. Such studies showed a global accuracy of 89.2% when a contingency matrix was used at

species-level definition of the typological level. The accuracy of the map was considered sufficient for it to be used as ground truth data in the comparison with the Forest Map of Spain.

A EUNIS (European Union Nature Information System) habitat legend of 13 classes was used as a reference for re-classification of the data sources under a single unified factor, and included:

– Surface standing waters (C1), – Temperate shrub heathland (F4), – Hedgerows (FA),

– Riparian Salix, Alnus and Betula woodland (G1-1), – Acidophilous Quercus-dominated woodland (G1-8), – Eucalyptus plantations (G2-81),

– Highly artificial coniferous plantations (G3-F), – Mixed deciduous and coniferous woodland (G4), – Coppice and early-stage plantations (G5-7), – Arable land and market gardens (I1), – Transport networks (J4),

– Buildings of cities, towns and villages (J1), – Low density buildings (J2).

Thematic resolution is coarser in the FMS, in which just 8 of the 13 classes are represented, owing to the aggregation effect imposed by the MMU. Thus, low density buildings, hedgerows, small ponds, etc. are not represented. The thematic resolution can strongly influ-ence the results of the indices (Baldwin et al.,2004; Buyantuyev and Wu,2007), and the GTM was therefore re-classified in both an 8-class legend (or “Equal Typological Legend”) and a 13-8-class legend (or “Extended Typological Legend”) for the analysis.

After reclassification, the maps were converted into raster format, to facilitate calculation of indices. A resolution of 1× 1 m of pixel size was adopted for rasterization.

2.3. Landscape metric analysis

Figure 2. Distribution of plots, and detail of one of the 500 m buffer areas (GTM).

landscape, i.e. fragmentation, heterogeneity and connectivity. In the study, 12 metrics were added to the 10 recommended in the FORSEE project to enhance the analysis of results.

As a standard procedure for calculation in the project, non-overlapping buffer areas of 500 m radius were defined around refer-ence points, and the landscape pattern inside them was characterized with the landscape metrics (See Fig.2). This procedure was comple-mented in the present study by calculation of metrics in buffer areas of 1000 and 1500 m radius, in the belief that the effects of the varia-tion in extension could clarify the behaviour of some of the indices. In these areas, overlapping was allowed, as the intention was com-parison of pairs of map sections corresponding to the two different sources, and not between buffer areas of the same data source, in which case partial replication of results could be expected. Three dif-ferent buffer sizes were used despite the sensitivity of the indices to changes in extent (Baldwin et al.,2004; Saura and Martínez-Millán, 2001; Wu,2004; Wu et al.,2002), as the comparisons were made among series of data calculated in buffers of equal extension. The metrics finally used were:

– Fragmentation: This group includes both composition met-rics (related to the number and relative importance of ele-ments in the landscape) and configuration metrics (related to those characteristics concerning geometrical aspects of landscape elements). Composition metrics included number of patches (NP); mean patch size (AREA_MN); and number of classes (N_CLASS) as initially defined in the FORSEE project; patch density (PD) was also added to the set. Configuration metrics included edge density (ED) and area-weighted mean shape index (SHAPE_AM), in the project; total edge (TE), standard deviation of patch size (AREA_SD), mean shape index (SHAPE_MN), standard deviation of shape index (SHAPE_SD), mean fractal dimension (FRAC_MN), standard deviation of fractal dimension (FRAC_SD), mean perimeter-area ratio (PARA_MN) and stan-dard deviation of perimeter-area ratio (PARA_SD) were also cal-culated.

– Heterogeneity: Shannon’s diversity (SHDI) and evenness (SHEI) indices were initially considered, and Simpson’s diversity in-dex (SIDI), modified Simpson’s diversity inin-dex (MSIDI), Simp-son’s evenness index (SIEI), modified SimpSimp-son’s evenness index (MSIEI), and number of classes (N_CLASS) were added. – Connectivity: Mean nearest neighbour distance between two

patches of the same forest type (ENN_MN) was complemented with deviation of nearest neighbour distance (ENN_SD) Details on the mathematical expressions and meaning of the indices calculated by FRAGSTATS can be found on the corresponding web-site (McGarigal et al.,2002). The buffer areas were defined in this study with 18 sampling points established in the National Forest In-ventory as a reference for the centre of the buffers. Landscape metrics were then calculated, for the portions of the maps corresponding to the buffer areas. The indices were calculated at landscape level, i.e. considering the full arrangement of patches in the calculation, with-out qualitative distinction among different classes.

2.4. Statistical analysis

Spearman’s rho Test was used to determine which landscape in-dices are related in the two types of cartography used (FMS and GTM). Spearman’s rho is a rank-order correlation coefficient that measures association at the ordinal level (Spearman,1904). It is a nonparametric version of the Pearson correlation based on ranks of the data rather than actual values (SPSS Inc., 2005). The use of ranks eliminates the sensitivity of the correlation test to the function link-ing the pairs of values (Pagano and Gauvreau,2001). In particular, the standard correlation test is used to find linear relations between test pairs, but the rank correlation test is not restricted in this way. Spear-man’s coefficient of rank correlation, denoted by rs, was calculated

by application of the following equation (Eq. (1)): rs= 1 −

6d2

i

Landscape metrics and forest landscapes Ann. For. Sci. 66 (2009) 301

Figure 3. Buffer areas around plot 1307. Left, FMS; right, GTM. The radii of the circular areas (from inner to outer) are 500, 1000 and 1500 m.

Where diis the difference in the ranks given to the values of the two

variables for each item of data. This is only an equivalent equation when there are no tied ranks, and if there are only a few of these, the equation provides an adequate approximation.

3. RESULTS

3.1. Misclassification errors and aggregation

During the analysis, two factors were identified in the FMS that could affect the results in the comparison process. Firstly, the presence of misclassified patches, i.e., where codification of the element in the map does not correspond to the real world. As the indices were calculated at the landscape level, there was no qualitative distinction among classes, and the in-fluence can be only quantitative, and directly affect those met-rics related to the number of classes and/or diversity. Secondly, the effects caused by aggregation. These were assumed to oc-cur, as the differences between the two data sources as regards MMU were known. However, it should be emphasised that the aggregation of spatial data affected composition and configu-ration of the map, and thus affected the results of the indices as shown in the following paragraph.

3.2. Application of metrics

Direct numerical comparison in absolute terms of the re-sults of landscape metrics calculated in the FMS and the GTM shows large differences among most of the indices, indepen-dently of the size of the buffer area. As an example, the graph-ical and numergraph-ical differences for the buffer areas located around plot No. 1307 are shown in Figure3and TableI.

These differences are especially noteworthy in the composi-tion indices chosen to assess fragmentacomposi-tion. For instance, dif-ferences between the maps for NP or PD reflect strong diver-gence between the two map sources, with higher values ob-tained with GTM. Similar trends were observed with ED and TE, as well as AREA_MN. Values also diverge depending on

the GTM legend, with an obvious decline in NP, PD, TE and ED, and increase in AREA_MN, in the values calculated for the “equal” typological legend.

A regards indices accounting for spatial configuration, it is important to note the different behaviour of PARA_MN, and both SHAPE_MN and FRAC_MN. Values of the former var-ied greatly depending on the data source, whereas the latter two were closer in range. However, the area weighted shape in-dex SHAPE_AM revealed important differences between the two data sources. Differences among values concerning GTM legends are minimal in all metrics showing spatial complexity. ENN_MN, related to connectivity, provided very different val-ues depending on the data source used, including those related to the typological legend.

Finally, diversity indices showed important differences be-tween data sources. Such differences were greater for SHDI and MSIDI. Furthermore, all the diversity indices showed a decrease in the GTM equal typological legend, and a greater decrease in MSIDI.

3.3. Statistical analysis

The analysis involving comparison among Spearman’s Rho values revealed correlation between FMS and GTM for some of the indices. Nevertheless, only TE, N_CLASS, and all the diversity indices showed statistical significant correlations be-tween the two maps at any of the three scales used. Other in-dices, such as NP, ED, AREA_MN, SHAPE_AM, PARA_SD, ENN_SD, FRAC_MN and FRAC_SD, showed some degree of correlation at one or two of the scales used in the analy-sis. AREA_SD, SHAPE_SD, and ENN_MN did not show any trace of correlation among the results for GTM and FMS at any of the scales. The values for all the calculated metrics are shown in TableII.

The response of the indices to the correlation analysis can be classified as follows:

(a) Values decrease sharply with the increase in the ex-tension of the buffer area. This is the case of metrics that

Table I. Example of the results for the analysis of the two map sources and the three buffers.

No. 1307

Buffer distance = 500 m Buffer distance = 1000 m Buffer distance = 1500 m

FMS GTM FMS GTM FMS GTM

Ext. T. L. Eq. T. L. Ext. T. L. Eq. T. L. Ext. T. L. Eq. T. L.

NP 7 117 87 12 340 218 16 614 427 PD 8.91 148.97 110.77 3.84 108.77 69.74 2.28 87.30 60.71 TE 4931 28582 26016 15487 102336 92963 32714 198218 182088 ED 62.78 363.92 331.25 49.55 327.40 297.41 46.52 281.84 258.91 AREA_MN 11.22 0.67 0.90 26.05 0.92 1.43 43.96 1.15 1.65 AREA_SD 10.21 1.77 2.05 33.01 2.65 3.32 80.09 4.67 5.64 SHAPE_MN 1.59 1.98 2.10 1.79 1.94 2.12 2.12 1.95 2.08 SHAPE_AM 1.80 2.38 2.33 2.26 2.91 2.94 2.95 3.32 3.34 SHAPE_SD 0.26 1.91 2.17 0.45 2.32 2.86 0.62 2.09 2.46 FRAC_MN 1.08 0.00 1.15 1.11 1.16 1.16 1.13 1.16 1.17 FRAC_SD 0.02 0.00 0.12 0.06 0.13 0.15 0.04 0.13 0.15 PARA_MN 399.13 3683.77 3510.77 1222.35 4139.83 3528.94 685.39 5014.01 4948.74 PARA_SD 371.77 5972.68 6807.04 2799.17 7167.00 7543.18 953.05 8620.24 9444.82 ENN_MN 215.42 42.57 28.98 173.80 42.93 45.86 159.59 40.71 42.32 ENN_SD 128.36 80.30 41.94 111.59 104.64 102.51 120.58 95.91 101.22 SHDI 1.29 1.79 1.56 1.25 1.93 1.66 1.28 1.96 1.75 SIDI 0.70 0.78 0.75 0.68 0.81 0.76 0.68 0.83 0.80 MSIDI 1.21 1.52 1.38 1.15 1.65 1.44 1.13 1.76 1.61 SHEI 0.93 0.72 0.75 0.90 0.78 0.80 0.71 0.79 0.84 SIEI 0.94 0.85 0.85 0.91 0.88 0.87 0.81 0.90 0.91 MSIEI 0.88 0.61 0.66 0.83 0.66 0.69 0.63 0.71 0.77 N_CLASS 4 12 8.00 4 12 8.00 6 12 8.00

Ext.T.E.: Extended Typological Legend (13 classes); Eq.T.E.: Equal Typological Legend (8 classes).

include density values such as PD and ED, composition met-rics such as AREA_MN, and configuration metmet-rics such as SHAPE_AM. The values of these parameters show significant correlations at any of the typological scales for the lower buffer size, but the degree of correlation decreases with the wider ex-tensions. There are various reasons for this, depending on the metrics concerned (see Discussion), and in general terms the correlation was higher for the extended typological legend in GTM.

(b) Values with more or less consistent response in the cor-relation. These may show some variation or a decrease in the absolute values for the correlation, but in general such correla-tion is significant throughout the different extensions. This re-sponse was shown by TE, and by the “diversity” metrics, such as N_CLASS, SHDI, SIDI, SHEI, SIEI, MSIDI and MSIEI. The correlation was generally slightly higher for the Extended Typological Legend in TE, and for the Equal Typological Leg-end in the other metrics.

(c) Inconsistent response. Correlation varies with no appar-ent trend related to the extension. This behaviour was shown by FRAC_MN, FRAC_SD, PARA_SD, ENN_SD and to some degree by NP.

4. DISCUSSION AND CONCLUSIONS

4.1. Scale issues and the results in landscape indices

The information displayed by FMS and GTM for the same geographical area is organized differently. The differences in

organization of the information are due to the different criteria used for their production, and are closely dependent on the in-herent characteristics of the elements that structure landscapes, such as their shape, abundance or spatial distribution. General-ization is imposed in the FMS by its resolution and the MMU used, causing aggregation of spatial information and resulting in a shift or ‘jump’ in the scale to the represented pattern from that in the GTM.

Landscape metrics and forest landscapes Ann. For. Sci. 66 (2009) 301

Table II. Values of Spearman’s Rho indices showing statistical correlations. Results are shown for the three different buffer areas used, and

comparing the two typological levels for the calculation. Asterisk (*) indicates significant correlation at P= 0.05 (bilateral); double asterisk (**) indicates significant correlation at P= 0.01 (bilateral).

Spearman’s Rho

Landscape metric Buffer distance = 500 m Buffer distance = 1000 m Buffer distance = 1500 m

Exp. Eq. Exp. Eq. Exp. Eq.

NP 0.498* 0.438 0.602** 0.557* 0.465 0.361 PD 0.486* 0.430 0.268 0.188 0.011 -0.98 TE 0.696** 0.665** 0.626** 0.610** 0.657** 0.606** ED 0.669** 0.642** 0.385 0.373 0.259 0.079 AREA_MN 0.486* 0.430 0.268 0.188 0.011 -0.98 AREA_SD 0.102 0.080 0.236 0.158 0.030 -0.005 SHAPE_MN -0.430 -0.350 -0.314 0.002 0.077 0.346 SHAPE_AM 0.711** 0.622** 0.278 0.257 -0.391 -0.410 SHAPE_SD -0.096 -0.034 -0.437 -0.321 -0.267 -0.038 FRAC_MN -0.420 0.006 0.589* 0.536* -0.201 0.183 FRAC_SD -0.264 0.027 0.546* 0.525* 0.048 0.036 PARA_MN 0.373 0.348 0.273 0.342 -0.011 -0.90 PARA_SD 0.377 0.402 0.573* 0.519* -0.038 -0.032 ENN_MN 0.147 0.137 0.106 0.117 0.152 0.042 ENN_SD 0.262 0.170 0.613** 0.539* 0.263 0.150 SHDI 0.801* 0.808** 0.395 0.482* 0.364 0.662** SIDI 0.816** 0.824** 0.643** 0.738** 0.558* 0.761** MSIDI 0.816** 0.824** 0.643** 0.738** 0.548* 0.761** SHEI 0.752** 0.783** 0.564* 0.503** 0.317 0.552* SIEI 0.822** 0.839** 0.610** 0.643** 0.633** 0.759** MSIEI 0.801** 0.790** 0.682** 0.529** 0.595** 0.692** N_CLASS 0.682** 0.660** 0.565** 0.700** 0.341 0.521*

as ENN_MN when applied to FMS, as the computation of Eu-clidean distances in the absence of small patches affects the overall results.

As a consequence, there were important differences be-tween the results obtained with the indices used in the FMS and in the GTM. Even when this is an obvious effect tak-ing into account the divergence in the information displayed by each data source, it is important to underline that the pat-terns or processes analysed with landscape indices should be consistent with the resolution of the data sources. In general terms, the MMU set the lower limit for resolution in data in vectorial maps, with extent being the upper limit. There-fore, detection of landscape patterns is constrained by such limits (Corry and Nassauer,2005; Thompson and McGarigal, 2002). In addition to the spatial scale, the typological scale is a source of variation in the values of the metrics. This is evident from the present results, especially when the results associ-ated with the extended and the equal typological legends in GTM are compared. The variation in the values of landscape metrics associated with the change in typological or thematic scale is well documented in the literature, and has been specif-ically addressed in recent studies (Bailey et al.,2007a;2007b; Buyantuyev and Wu,2007; Huang et al., 2006), in which it has generally been concluded that metrics behave differently, both quantitatively and qualitatively, depending on the exten-sion analysed.

4.2. Correlation in results from FMS and GTM

Once the above considerations have been taken into ac-count, pattern analysis with landscape metrics can provide use-ful results. Correlation analysis may help to reveal the possibil-ities for correct use of landscape indices in low-resolution vec-torial forest maps, such as FMS. In the present study it enabled identification of metrics that retrieve information about the landscape pattern when they are interpreted not by their abso-lute value, but by their relative variation across scales. Never-theless, even when interesting results are apparently obtained in the correlation analysis, they must be interpreted cautiously. With the first type of results (correlation decreasing with the extension of buffer zones) the values obtained for AREA_MN and SHAPE_AM are considered to be affected to a great extent by the methodology. The position of the stand (i.e., the centre of the buffer) was deliberately placed inside forest landscapes, and therefore large forested patches are likely to be found in the immediate range of the stand, which is reflected by the sim-ilar “patchiness” patterns in the two data sources analysed. As the extension increases, the landscape pattern may include dif-ferent, non-forested elements, and there is a higher probabil-ity that the GTM will include patches smaller than the MMU of the FMS. Thus, the sensitivity of AREA_MN, (and conse-quently in SHAPE_AM, due to its area-weighting) to changes in the spatial pattern affects the correlation between scales.

Density metrics, PD and ED, are highly sensitive to extent in correlation analysis, a characteristic that is not shared by the indices representing their absolute values, NP and TE, re-spectively. This may be due to the differences reported by Wu et al. (2002) regarding the responses to changes in extension between PD and TE. The metrics NP and FRAC_MN were classified as erratic in their response to the scale because of the impossibility in finding a clear trend in the evolution of the scale-related results. TE is included in the group of the metrics that show a more consistent response across scales, together with the whole group of diversity indices, including SHDI, SIDI, SHEI, SIEI, MSHEI and MSIEI. This type of re-sponse is obviously of more interest for the objectives of this study. TE reflects nicely the complexity of the landscape at the two scales analysed, probably because measuring the total bor-der length between patches involves less exposure to the area effects described above.

The diversity measures selected for the analysis are mostly based on the contribution (i.e. proportion) of each different habitat in the studied portions of landscape. They are quite sen-sitive to the type of legend used, because of the method of cal-culation, which affects the total proportion of each habitat. In this case, the higher values of correlation were observed when

equal-legend maps were compared. The best results were

pro-vided by SIDI and MSIDI, probably because of the straightfor-ward calculations involved (based respectively on the sum of the squares of the proportion of classes, and on the logarithm of the sum).

4.3. Use of landscape metrics for assessing

fragmentation, heterogeneity and connectivity at different scales

The improper use of landscape indices occurs when there is inconsistency between the structure represented on the map and the process that we want to analyse with the metric. Despite interesting results obtained with fine-grained maps (Bailey et al.,2007b; Martin-Garcia et al.,2006), it is difficult to infer biodiversity characteristics in forest landscapes from absolute results of landscape indices, especially when applied to low resolution maps. Correspondingly, for the sake of relia-bility in the analysis, it must be clear that not all aspects of the complexity of forest landscapes can be characterised by appli-cation of landscape metrics. Nevertheless, their relative values can be used for assessing some aspects of such complexity.

Among the three groups of indices used in the FORSEE project to represent forest pattern complexity, namely frag-mentation, connectivity and heterogeneity, the latter, com-posed of diversity metrics, showed more scale-independence in the results than the other indices when considering relative values. Thus, diversity metrics are recommended for the anal-ysis of heterogeneity, taking into account that the different in-dices do not describe the same landscape properties (Lausch and Herzog,2002; Nagendra,2002). For instance SHDI may be more appropriate for taking into consideration rare cover types, and conversely SIDI may be more appropriate when the interest is focused on dominant cover types. Fragmentation

in-dices in this study only include TE as acceptable regarding scale-independence, and none of the connectivity indices are acceptable. From the results obtained we then recommend the use of edge metrics, especially those reporting absolute values (TE), for the characterization of landscape configuration. The use of contrast edge metrics, such as the Total Edge Contrast

Index (Botequilha and Ahern,2002; Botequilha et al.,2006; McGarigal et al., 2002) is recommended for enhancing eco-logical analysis of fragmentation. However, other aspects of fragmentation or connectivity, in areas where such factors de-pend on fine-grained landscape elements (like tiny patches or corridors) require greater resolution. To solve this, we suggest the use of multi-scale strategies, with low resolution cartog-raphy to assess the general characteristics of landscape het-erogeneity and configuration, and to identify heterogeneous spots, and derivation of high-resolution analysis in the specific spots, thereby decreasing the costs of the analysis. Similar ap-proaches have been used in diverse examples in other fields of forest and ecosystem management (see e.g., Klijn, 1991; Nakamura et al.,2005; Sims et al.,1995).

In summary, from the results obtained here, some additional advice can be given in order to prevent misuse of landscape indices when applied to low-resolution, vectorial forest maps. In general, such maps can be used to:

– Support definition of forest landscape units;

– Describe the general structure of the landscape pattern, particularly when comparisons are made between land-scapes;

– Estimate regional (supra-local) forest diversity; – Give geographical sense to general forest statistics; – Define spatially the general evolution in main forest

ar-eas, including those aspects inferred from their shape, by comparing maps of the same geographical area at different times.

. . . And should not be used to:

– Estimate accurately the total forest area in highly frag-mented landscapes (such as that in the case studied), be-cause of the accumulation effect of small forest patches in the overall results;

– Assess general forest connectivity, as the effect of the patches ignored due to the resolution of data may be missed;

– Assess fragmentation at local levels.

Acknowledgements: This study was supported by the European

Union funded INTERREG III-B project 020-FORSEE (Sustainable management of forests: a European network of pilot zones for putting this into operational effect), and by a research contract with the Uni-versity of Santiago de Compostela supported by the Galician regional government (Isidro Parga Pondal (PGIDIT) programme). We also thank Dr Christine Francis for correcting the English grammar of the text.

REFERENCES

Landscape metrics and forest landscapes Ann. For. Sci. 66 (2009) 301

Scientific challenges and opportunities. EFI Proceedings No. 49, European Forest Institute.

Bailey D., Billeter R., Aviron S., Schweiger O., and Herzog F., 2007a. The influence of thematic resolution on metric selection for biodi-versity monitoring in agricultural landscapes. Landsc. Ecol. 22: 461– 473.

Bailey D., Herzog F., Augenstein I., Aviron S., Billeter R., Szerencsits E., and Baudry J., 2007b. Thematic resolution matters: Indicators of landscape pattern for European agro-ecosystems. Ecological Indicators 7: 692–709.

Baldwin D.J.B., Weaver K., Schnekenburger F., and Perera A.H., 2004. Sensitivity of landscape pattern indices to input data characteristics on real landscapes: implications for their use in natural disturbance emulation. Landsc. Ecol. 19: 255–271.

Bengtsson J., Nilsson S.G., Franc A., and Menozzi P., 2000. Biodiversity, disturbances, ecosystem function and management of European forests. For. Ecol. Manage. 132: 39–50.

Benson B.J. and MacKenzie M.D., 1995. Effects of sensor spatial resolu-tion on landscape structure parameters. Landsc. Ecol. 10: 113–120. Botequilha Leitao A. and Ahern J., 2002. Applying landscape

ecologi-cal concepts and metrics in sustainable landscape planning. Landsc. Urban Plann. 59: 65–93.

Botequilha Leitao A., Miller J., Ahern J., and McGarigal K., 2006. Measuring landscapes. A planner’s handbook, Island Press, Washington, 245 p.

Buyantuyev A. and Wu J., 2007. Effects of thematic resolution on land-scape pattern analysis. Landsc. Ecol. 22: 7–13.

Corry R.C. and Nassauer J.I., 2005. Limitations of using landscape pat-tern indices to evaluate the ecological consequences of alpat-ternative plans and designs. Landsc. Urban Plann. 72: 265–280.

Falcao A.O. and Borges J.G., 2005. Designing decision support tools for Mediterranean forest ecosystems management: a case study in Portugal. Ann. For. Sci. 62: 751–760.

Franklin J.F. and Forman R.T.T., 1987. Creating landscape patterns by forest cutting: Ecological consequences and principles. Landsc. Ecol. 1: 5–18.

Frohn R.C., 1998. Remote sensing for landscape ecology. New metric indicators for monitoring, modeling, and assessment of ecosystems, Lewis Publishers, Boca Raton, 99 p.

Frohn R.C. and Hao Y., 2006. Landscape metric performance in analyz-ing two decades of deforestation in the Amazon Basin of Rondonia, Brazil. Remote Sens. Environ. 100: 237–251.

Gonzalez J.R., Palahí M., and Pukkala T., 2000. Integrating fire risk con-siderations in forest management planning in Spain – a landscape level perspective. Landsc. Ecol. 20: 957–970.

Gustafson E.J., 1998. Quantifying Landscape Spatial Pattern: What Is the State of the Art? Ecosystems 1: 143–156.

Hargis C.D., Bissonette J.A., and David J.L., 1998. The behavior of land-scape metrics commonly used in the study of habitat fragmentation. Landsc. Ecol. 13: 167–186.

Hoover S.R. and Parker A.J., 1991. Spatial components of biotic diversity in landscapes of Georgia, USA. Landsc. Ecol. 5: 125–136.

Huang C., Geiger E.L., and Kupfer J.A., 2006. Sensitivity of landscape metrics to classification scheme. Int. J. Remote Sens. 27: 2927–2948. Jelinski D.E. and Wu J., 1996. The modifiable areal unit problem and

implications for landscape ecology. Landsc. Ecol. 11: 129–140.

Klijn F., 1991. Hierarchical classification of ecosystems: a tool for sus-ceptibility analysis and quality evaluation for environmental policy. In: Ravera, O. (Ed.), Terrestrial and aquatic ecosystems. Perturbation and recovery, Ellis Horwood, London, pp. 80–89.

Lausch A. and Herzog F., 2002. Applicability of landscape metrics for the monitoring of landscape change: issues of scale, resolution and interpretability. Ecol. Indic. 2: 3–15.

Li H. and Wu J., 2004. Use and misuse of landscape indices. Landsc. Ecol. 19: 389–399.

Li X.Z., He H.S., Bu R.C., Wen Q.C., Chang Y., Hu Y.M., and Li Y.H., 2005. The adequacy of different landscape metrics for various land-scape patterns. Pattern Recogn. 38: 2626–2638.

Lindenmayer D.B., Margules C.R., and Botkin D.B., 2000. Indicators of biodiversity for ecologically sustainable forest management. Conserv. Biol. 14: 941–950.

Lloret F., Calvo E., Pons X., and Diaz-Delgado X., 2002. Wildfires and landscape patterns in the Eastern Iberian peninsula. Landsc. Ecol. 17: 745–759.

Löfman S. and Kouki J. 2003. Scale and dynamics of a transforming for-est landscape. For. Ecol. Manage. 175: 247–252.

Marceau, D.J., 1999. The scale issue in social and natural sciences. Can. J. Remote Sens. 25: 347–356.

Marey M.F., 2003. Tenencia de la tierra en Galicia: Modelo para la carac-terización de los propietarios forestales. Doctoral Thesis. University of Santiago de Compostela.

Martin-Garcia J., Herve J., and Diez J.J., 2006. Landscape metrics as surrogates for bird assemblages in biodiversity indicators. Indicators for Sustainable forest management in cultivated forests: International Conference FORSEE Project Final Meeting, 11–13 December 2006, Porto (Portugal).

McAlpine C.A. and Eyre T.J., 2002. Testing landscape metrics as indica-tors of habitat loss and fragmentation in continuous eucalypt forests (Queensland, Australia). Landsc. Ecol. 17: 711–728.

McGarigal K., Cushman S.A., Neel M.C., and Ene E., 2002. FRAGSTATS: Spatial Pattern Analysis Program for Categorical Maps. University of Massachussetts. Available on the internet, URL:

www.umass.edu/landeco/research/fragstats/fragstats.html.

Nagendra H., 2002. Opposite trends in response for the Shannon and Simpson indices of landscape diversity. Applied Geography 22: 175– 186.

Nakamura F., Inahara S., and Kaneko M., 2005. A hierarchical ap-proach to ecosystem assessment of restoration planning at regional, catchment and local scales in Japan. Landscape and Ecological Engineering 1: 43–52.

O’Neill R.V., Krummel J.R., Gardner R.H., Sugihara G., Jackson B., DeAngelis D.L., Milne B.T., Turner M.G., Zygmunt B., Christensen S.W., Dale V.H., and Graham R.L., 1988. Indices of landscape pat-tern. Landsc. Ecol. 1: 153–162.

Pagano M. and Gauvreau K., 2001. Principios de Bioestadística. Thomson Learning, México D.F., 525 p.

Päivinen R. and Köhl M., 2005. European Forest Information and Communication System (EFICS), Technical Report 17, European Forest Institute. Available on the internet, URL:http://www.efi.fi/ publications/technical-reports/17.html(last visit 23/07/2007). Riitters K.H., Wickham J.D., O’Neill R.V., Jones K.B., Smith E.R.,

Coulston J.W., Wade T.G., and Smith J.H., 2002. Fragmentation of continental United States forests. Ecosystems 5: 815–822.

Romme W.H., 1982. Fire and landscape diversity in subalpine forests of Yellowstone National Park. Ecol. Monogr. 52: 199–221.

Saura S., 2002. Effects of minimum mapping unit on land cover data spa-tial configuration and composition. Int. J. Remote Sens. 23: 4853– 4880.

Saura S., 2004. Effects of remote sensor spatial resolution and data aggre-gation on selected fragmentation indices. Landsc. Ecol. 19: 197–209. Saura S. and Carballal P., 2004. Discrimination of native and exotic forest patterns through shape irregularity indices: an analysis in the land-scapes of Galicia, Spain. Landsc. Ecol. 19: 647–662.

Saura S. and Martínez-Millán J., 2001. Sensitivity of landscape pattern metrics to map spatial extent. Photogram. Eng. Remote Sens. 67: 1027–1036.

Sims R.A., Mackey B.G., and Baldwin K.A., 1995. Stand and landscape level applications of a forest ecosystem classification for northwest-ern Ontario, Canada. Ann. For. Sci. 52: 573–588.

Spearman C., 1904. The proof and measurement of association between two things. Am. J. Psychol. 15: 72–101.

SPSS Inc., 2005. SPSSTM version14.0.1. Statistical software. Statistical Products and Service Solutions Inc., Chicago.

Thompson C.M. and McGarigal K., 2002. The influence of research scale on bald eagle habitat selection along the lower Hudson River, New York (USA). Landsc. Ecol. 17: 569–586.

Trani M.K. and Giles R.H., 1999. An analysis of deforestation: Metrics used to describe pattern change. For. Ecol. Manage. 114: 459–470. Turner M.G., O’Neill R.V., Gardner R.H., and Milne B.T., 1989. Effects

of changing spatial scale on the analysis of landscape pattern. Landsc. Ecol. 3: 153–162.

Von Gadow, K., Pukkala, T. and Tome, M., 2000. Sustainable Forest Management. Kluwer Academic Publishers, Dordrecht, 356 p. Wu J., 2004. Effects of changing scale on landscape pattern analysis:

scal-ing relations. Landsc. Ecol. 19: 125–138.